Doktorand*in
Daniel Felder, M.Sc.
Forschungsinteresse
Die Forschung von Daniel Felder beschäftigt sich mit dem gekoppelten Ladungstransport von Ionen und Elektronen in Strukturen aus leitfähigen Polymeren, Elektrolyten und Polyelektrolyten und der Anwendung in neuromorphen, an die Struktur des menschlichen Gehirns angelehnten, Geräten. Dabei werden mit elektrochemischen Methoden und direkten numerischen Simulationen die Eigenschaften der Geräte schrittweise verstanden und hin zu zukünftigen Anwendungen optimiert. Ziel der Forschung ist es Möglichkeiten zu entwickeln um Informationen in weichen polymerischen System zu verarbeiten.
Daniel Felder ist Teil der AG Wessling.
Projects
Publications
Titel/Autoren | DOI-LINK | Magazine | Jahre | |
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Toward Decentralized Wastewater Treatment: A Flow-through Module Using Microtubular Gas Diffusion Electrodes for Micropollutants Removal
M. Mohseni, D. Felder, K. Percin, M. Thönes, M. Gassenmeier, R. Kupec, C. Weidlich, J. Linkhorst, R. G. Keller and M. Wessling
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https://doi.org/10.1016/j.jhazmat.2023.131987 | Journal of Hazardous Materials | 2023 | |
Spiking Neural Networks Compensate for Weight Drift in Organic Neuromorphic Device Networks
D. Felder, J. Linkhorst and M. Wessling
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https://doi.org/10.1088/2634-4386/accd90 | Neuromorphic Computing and Engineering | 2023 | |
Peptide-Functionalized Electrospun Meshes for the Physiological Cultivation of Pulmonary Alveolar Capillary Barrier Models in a 3D-Printed Micro-Bioreactor
P. Jain, S. B. Rauer, D. Felder, J. Linkhorst, M. Möller, M. Wessling and S. Singh
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https://doi.org/10.1021/acsbiomaterials.3c00047 | ACS Biomaterials Science & Engineering | 2023 | |
Reminding Forgetful Organic Neuromorphic Device Networks
D. Felder, K. Muche, J. Linkhorst and M. Wessling
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https://doi.org/10.1088/2634-4386/ac9c8a | Neuromorphic Computing and Engineering | 2022 | |
Hands-on Kinetic Measurements and Simulation for Chemical Process Engineering Students
S. Herrmann, D. Felder, M. Padligur, S. Brosch, M. Geiger, F. Stockmeier, K. Baitalow, D. Rall, R. Femmer, F. Roghmans, M. Hauser, J. Mehlis, J. Linkhorst and M. Wessling
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https://doi.org/10.1016/j.ece.2022.08.001 | Education for Chemical Engineers | 2022 | |
Coupled Ionic–Electronic Charge Transport in Organic Neuromorphic Devices
D. Felder, R. Femmer, D. Bell, D. Rall, D. Pietzonka, S. Henzler, J. Linkhorst and M. Wessling
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https://doi.org/10.1002/adts.202100492 | Advanced Theory and Simulations | 2022 | |
Wet-Spun PEDOT/CNT Composite Hollow Fibers as Flexible Electrodes for H2O2 Production**
Q. Cui, D. J. Bell, S. Wang, M. Mohseni, D. Felder, J. Lölsberg and M. Wessling
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https://doi.org/10.1002/celc.202100237 | ChemElectroChem | 2021 | |
Porous PEDOT:PSS Particles and Their Application as Tunable Cell Culture Substrate
S. B. Rauer, D. J. Bell, P. Jain, K. Rahimi, D. Felder, J. Linkhorst and M. Wessling
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https://doi.org/10.1002/admt.202100836 | Advanced Materials Technologies | 2021 | |
Discrepancy of particle passage in 101 mask batches during the first year of the Covid-19 pandemic in Germany
L. T. Hirschwald, S. Herrmann, D. Felder, A. M. Kalde, F. Stockmeier, D. Wypysek, M. Alders, M. Tepper, J. Rubner, P. Brand, T. Kraus, M. Wessling and J. Linkhorst
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https://doi.org/10.1038/s41598-021-03862-z | Scientific Reports | 2021 | |
Towards synergistic oscillations in enzymatically active hydrogel spheres
D. J. Bell, D. Felder, W. G. von Westarp and M. Wessling
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https://doi.org/10.1039/D0SM01548B | Soft Matter | 2020 | |
Two-Photon Vertical-Flow Lithography for Microtube Synthesis
J. Lolsberg, A. Cinar, D. Felder, G. Linz, S. Djeljadini and M. Wessling
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https://www.doi.org/10.1002/smll.201901356 | Small | 2019 |